posted on 2020-08-06, 22:18authored byDapeng Wang, You-Liang Zhu, Yuehua Zhao, Christopher Y. Li, Ashis Mukhopadhyay, Zhao-Yan Sun, Kaloian Koynov, Hans-Jürgen Butt
Janus
nanoparticles could exhibit a higher interfacial activity
and adsorb stronger to fluid interfaces than homogeneous nanoparticles
of similar sizes. However, little is known about the interfacial diffusion
of Janus nanoparticles and how it compares to that of homogeneous
ones. Here, we employed fluorescence correlation spectroscopy to study
the lateral diffusion of ligand-grafted Janus nanoparticles adsorbed
at water/oil interfaces. We found that the diffusion was significantly
slower than that of homogeneous nanoparticles. We carried out dissipative
particle dynamic simulations to study the mechanism of interfacial
slowdown. Good agreement between experimental and simulation results
has been obtained only provided that the flexibility of ligands grafted
on the nanoparticle surface was taken into account. The polymeric
ligands were deformed and oriented at an interface so that the effective
radius of Janus nanoparticles is larger than the nominal one obtained
by measuring the diffusion in bulk solution. These findings highlight
further the critical importance of the ligands grafted on Janus nanoparticles
for applications involving nanoparticle adsorption at an interface,
such as oil recovery or two-dimensional self-assembly.